Tyco 4100U - Manuals

v Copyrights and Trademarks ................................................................................ i Approvals ............................................................................................................. i Manufacture ..........................................................

vii Step 6. Installing LED/Switch Modules into Expansion Bays (4100U) .......... 2-20 Overview .................................................................................................... 2-20 The LED/Switch User Interface ................................................................. 2-2...

viii Local Mode Specifications ........................................................................... 4-5 LEDs ............................................................................................................ 4-6 Card Specifications ......................................................

ix Wiring Illustrations ..................................................................................... 5-17 Wired Media, Style 7 Wiring ..................................................................... 5-17 Fiber Optic, Style 7 Wiring .........................................................

xi Chapter 9 PC Software Connections ........................................ 9-1 Introduction .................................................................................................. 9-1 In this Chapter .........................................................................................

xii Appendix A The Device Configuration DIP Switch ..................A-1 Overview ......................................................................................................A-1 Appendix B Programming Requirements ................................B-1 Introduction ..............................

xiii Appendix G Compatible Batteries............................................ G-1 Appendix H 4100U Specifications .............................................H-1 General ....................................................................................................... H-1 Fuses ...............

xiv Figure 1-1. Standalone 4100U System ........................................................... 3 Figure 1-2. MINIPLEX 4100U System ............................................................ 5 Figure 1-3. Hub/Ring Configuration ................................................................ 6...

xv Figure 8-2. Mounting onto the Power Distribution Interface......................... 8-4 Figure 8-3. Mounting into 4100 (legacy) Bay ............................................... 8-5 Figure 8-4. DIP Switch SW1......................................................................... 8-6 Figure 8-...

1-1 The 4100/4100U is an expandable fire alarm system that can be used as a standalone system with one host panel, or as a wide-ranging system with several remote cabinets, with or without multiple host panels. This chapter is an overview of standalone, MINIPLEX, and network 4100 system concepts. Re...

1-2 The 4100U is available as a standalone system with one host panel, or as an expansive system with several remote back boxes, with or without multiple host panels. The type of configuration used depends on the size of the site into which it is being installed. The following types of configuration...

1-3 The standalone version of the 4100U is used for smaller or single-building applications. A standalone system is ideally placed into a small building that requires a limited number of notification appliances and initiating devices. If a small building is being expanded, or if other buildings are ...

1-4 The MINIPLEX version of the 4100 Fire Alarm System, which is designed for moderately larger applications than the standalone configuration, allows up to 1000 monitor and/or control points and 2000 annunciator points to be controlled by a single FACP. Like the standalone system, only one CPU is u...

1-5 The 4100 internal comms bus may be used to carry data from the CPU in the main cabinet to expansion equipment in a co-located cabinet. 4100 data from the CPU may be routed to remote cabinets (RTUs) in a MINIPLEX system by using the external RUI comms bus. An RUI line, routed from either the CPU ...

1-6 The 4100 can be expanded to a network system by using network interface cards (NICs). When a NIC is installed into a 4100 host panel, it is used to connect to other network nodes. Nodes may consist of other host 4100 panels, or they may be completely different: Graphical Command Centers (GCCs), ...

1-7 Network loops can be joined via physical bridge cards. There may be no more than two Style 7 network loops (two hub configurations) connected in tandem. For every two loops that are interconnected (using one physical bridge), there can be a maximum of three physical bridges used in a star config...

1-9 This section lists all cabinet (back box) PIDs for the 4100U Fire Alarm System. Empty cabinets with Doors (Cream Wrinkle)/ Number of bays Number of bays that can be fitted: • ME0447 18U x 210 Rack Cabinet, Window Door : 1-Bay • ME0268 21U x 310 Rack Cabinet, Window Door : 1-Bay • ME0255 28U x 31...

1-10 • 4100-0625 Transponder Interface Card • 4100-0160 Internet Interface Module (566-355). • 4100-9848AU System Power Supply, Australian version. • ME0456 Fan Control Module The following kits are available: • KT0419 A4 Document Holder, Stick-On, 3U High, Grey • KT0446 4100U Expansion Bay • KT0447...

2-1 4100U cabinets are available in one-, two-, and three-bay sizes. Each can be equipped with a solid or perspex door. This chapter describes how to mount all types of 4100U cabinets to a wall, and how to mount system card bays into the cabinets, modules to bays, etc. FACPs are assembled to order w...

2-3 Introduction to FACPs (4100U), Continued The 4100U Master motherboard that houses the CPU card is central to the 4100U system. It mounts in the first bay, occupying four inches of space on the right hand side. Neither has a card address DIP switch (the CPU is address 0). Figure 2-1. Master (CPU)...

2-5 The master controller daughter card LEDs indicate Bootloader status as shown in the table below. Table 2-1. Master Controller LEDs 1 through 4 Status Condition LED4 LED3 LED2 LED1 Bootloader Initialization On (0.25s), Off (0.25s) On (0.25s), Off (0.25s) On (0.25s), Off (0.25s) On (0.25s), Off (0...

2-6 The operator interface lets a user operate the panel. It provides alarm, trouble, and isolate status alerts, and lets the user review historical logs and perform diagnostics. Figure 2-3. Operator Interface The CPU bay can be equipped with many additional types of modules. The cards listed below ...

2-8 The FACP is powered by the SPS (System Power Supply), which gets its primary power from the AC mains and its secondary power from the backup batteries. The 24Vdc bulk power on the SPS is unregulated, and is divided into three feeds, i.e. 24V Card, 24V Signal, and 24V Aux Power. 24V Card which su...

2-10 The CPU, SPS, and all other modules to be mounted in the FACP cabinets must be configured to operate correctly in the system via their DIP switch and jumper ports. This section describes the hardware configuration for the CPU and SPS, since they will always be used in the CPU bay. The CPU mothe...

2-11 P4/P5 : The PDI can be configured to draw its power from different sources via P4 and P5. • To draw power from an XPS on the PDI, set jumpers on P4 and P5 to position 2 – 3. • To draw power from P1 (from the previous PDI or SPS), set jumpers on P4 and P5 to position 1 – 2 (default). • To remove...

2-12 Use the following directions to connect the CPU to the SPS and other motherboards. 1. Connect P3 on the SPS to P1 on the CPU motherboard using the 8 wire harness with eight-position Molex minifit connector (provided). 2. Make sure the 10 way, right angle header, connector P3 on the CPU is secur...

2-13 Figure 2-7, below, shows the interconnections between three bays in a host panel. 4100 POWER DISTRIBUTION INTERFACE ASSY 566-084 4100 POWER DISTRIBUTION INTERFACE ASSY 566-084 Figure 2-7. Bay-to-Bay Interconnections Panels with motherboards on the left side of the expansion bays require some no...

2-14 2. Connect the other end of the harness to the leftmost motherboard in the next bay, as described below. Make sure to route the wiring on the left side of the bay. • Insert the harness connector with the blue wire into the P2 connector. Note that the P2 connector has eight pins. Insert the harn...

2-15 This section contains guidelines and instructions on installing 4”x 5” cards and traditional motherboards into 4100U card bays. IMPORTANT: This section applies to aftermarket modules for expansion bays only. If you do not need to install any aftermarket modules at all, and if you have followed ...

2-16 • Motherboards can be installed on top of the PDI in expansion bays. The data and power that would normally be bussed via the PDI is instead routed across the boards via ribbon cable from one board to the next. • Up to eight 2” (51 mm) x 11 ½” (292 mm) motherboards can be installed in an expans...

2-19 Use the following procedure when installing motherboards in an expansion bay. Start with the second slot from the left and fill to the right. The mounting items are available as KT0468. 1. Orient the motherboard with the connector labeled J1 on the right and the header labeled P1 on the left. 2...

2-25 Figure 2-18. Assembling / Disassembling the LED Display Card User interface wiring consists of connecting the LED/switch controller card to the expansion bay’s power distribution interface (PDI), and connecting display cards to each other. This section describes both procedures. Continued on ne...

2-26 The following directions are complete instructions on interconnecting display cards and connecting the controller card to a power source. 1. Use Harness 734-008 to connect P2 on the controller card to one of the 4-pin connectors on the PDI. 2. If there are multiple controller cards, use Harness...

2-27 The 4100-0632 Terminal Block Utility Module is an all-purpose terminal block that mounts to an expansion bay, above or below the power distribution interface (PDI). Each module utilizes one block of mounting space. The terminal block utility module has two 16-position terminal blocks that accep...

3-29 4100 host panel and remote locations. This chapter describes the transponder installation procedure for all MINIPLEX systems in non-4100U systems. Refer to the page number listed in this table for information on a specific topic. Topic See Page # Introduction to MINIPLEX Systems (Non-4100U) 3-3...

3-30 The 4100 MINIPLEX Fire Alarm System uses transponder cabinets containing remote interface cards (RICs) to extend power and communication across large areas. MINIPLEX transponders allow the system to provide applications for up to 1000 monitor and/or control points and 2000 annunciator points (s...

3-31 Seventh floor Sixth floor Fifth floor Fourth floor Third floor Second floor First floor Speaker NAC TrueAlarm sensorsand MAPNET IIaddressable circuits RUI communicationswiring, twisted,shielded pair Audio riser wiring,twisted pair Legend: MINIPLEX transponderwith solid door MINIPLEX transponder...

3-32 The 4100 MINIPLEX system is comprised of a host panel containing everything required in a standalone cabinet (see Chapter 2), plus: • An RUI module in the master controller bay • One or more remote MINIPLEX transponder cabinets • A RIC II card in each transponder cabinet This section describes ...

3-35 This section contains guidelines and instructions for mounting the RUI and RIC II modules into 4100 cabinets. • The RUI motherboard mounts into the CPU bay or, if necessary, an expansion bay. • The RIC II mounts into expansion bays only. Review the following guidelines before installing a mothe...

3-36 The RIC II motherboard is installed into a remote transponder cabinet. Review the following guidelines before mounting RIC II motherboard. • If a power supply is installed in the bay, it must be installed on the far right of the bay and any relay modules must be installed in the slots immediate...

3-40 The illustration below applies to Class A and Class B wiring. 4100 MINIPLEX MASTER RIC 11565-233 MINIPLEX TRANSPONDER 562-856 W/565-217 COMMS "A" 8 1 COMMS "B" RUI TB1 TB1 RIC 11565-233 MINIPLEX TRANSPONDER 8 1 TB1 Figure 3-7. MINIPLEX Wiring Notes: 1. Power wiring is not shown....

4-1 MINIPLEX transponder interface cards (TICs) allow for data and power interconnections between the 4100 host panel and remote locations. This chapter describes the transponder installation procedure for 4100U MINIPLEX systems. Refer to the page number listed in this table for information on a spe...

4-2 The 4100U MINIPLEX system is comprised of a host panel containing everything required in a standalone cabinet (see Chapter 1), plus: • One or more remote MINIPLEX transponder cabinets • A transponder interface card (TIC) in each transponder cabinet This section describes each component in turn. ...

4-3 The local mode TIC contains an RUI input, port for connecting to other transponder modules, and terminal block for connecting to an optional Local Mode Controller. Local Mode Controllers are mounted remotely from the transponder. Installation instructions are supplied with the controller. Local ...

4-4 TB1 CH2 SEC- SEC+ SHLD PRI- PRI+ CH1/DAR SEC- SEC+ SHLD PRI- PRI+ 16 15 2 LED1 CH2 LED2 CH1/DAR 1 SEC 1 TB3 TB2 1 P2 1 TB1 21 SEC 2DAR CHANNEL OUT NAA IN NAA OUT NAA VOLUME R4 SW1 LED1 LED2 LED3LED4 DAR GROUND FAULT SEARCH ACTIVE PDI RECEIVE ENABLE PRIMARY RECEIVE SECONDARY RECEIVE DIGITAL RISER...

4-6 The TICs have the following LEDs: LED1. Illuminates to indicate communication loss with the CPU. LED2. Illuminates when an RUI ground fault search is active. LED3. Illuminates when Local Mode is active. LED4. Illuminates to indicate an RUI Style 7 primary trouble. LED5. Illuminates to indicate a...

4-10 4100 POWER DISTRIBUTION INTERFACE ASSY 566-084 4100 POWER DISTRIBUTION INTERFACE ASSY 566-084 LED4 SW1 LED1 TB2 PRI LED2 P1 P3 LED5 TB3 SEC RUI TMPR SW 24C INPUT SHLD 4100 COMM LOSS RUIG.F. SEARCH AUDIO RISER CARD HARNESS734-008 TI SPS OR RPS C PDI 1 PDI 2 HARNESS 734-078 P1 P6 POWER/COMM Conne...

4-11 The TIC must be connected to the host panel via RUI cabling. This section explains how to wire the two together, and how to set up a system with multiple transponders connected to the same host panel. RUI cabling can be accomplished either through Class A or Class B wiring. Class A wiring allow...

5-1 A standalone or MINIPLEX 4100 system becomes a network node when a 4100 Network Interface Card (NIC) or other compatible network card is installed and connected to another network node. How network cards connect to each other depends on the type of media network cards being used. Refer to the pa...

5-2 This chapter describes how to turn a standalone or MINIPLEX FACP into a network node. This process consists of the following: Step 1. Configuring cards for operation (using DIP switches and jumper ports) Step 2. Mounting media cards to the network interface card (NIC) Step 3. Mounting network ca...

5-3 The Network Interface Card (NIC) is a slave card that uses the standard 4100 serial bus to communicate with the master. The NIC connects FACPs in a network, allowing for communication between each panel via fiber, modem, or twisted shielded pair wire. The NIC is designed to be connected in a poi...

5-5 The figures below are illustrations of two motherboards apart from the default CPU motherboard that can be used with the 4100 NIC. • The 565-274 Master Motherboard holds two daughter cards: the 4100 master controller card and the 4100 NIC. • The 565-275 Class B Motherboard holds the 4100 NIC by ...

5-6 There are two approved modules that can be plugged into the 4100-6014 NIC: • 4100-6057 Fiber-Optic Media Card (565-261) • 4100-6056 Wired Media Card (565-413) Each module is shown below. Figure 5-4. The 4100/4120-0143 Fiber-Optic Media Card RESERVED (TB1) Figure 5-5. The 4100/4120-0142 Wired Med...

5-7 Table 5-1. 4100 NIC & Media Cards - Electrical and Environmental Specifications Electrical Specifications Network Interface Card Startup, no media cards: 8 VDC @ 110 mA Nominal, no media cards: 20 to 32 VDC @ 0 mA Fiber Media Card Using 24 V power supply: 20 VDC @ 140 mA max. Using 5 V power...

5-9 The 4100-6014 Network Interface Card (NIC) uses media cards to connect to other NICs. This section describes how the media cards are mounted onto NICs. NICs connect to each other via the three types of media cards. The types of media cards in the right and left ports are determined by the type o...

5-10 The 4100 NIC daughter card, shown in Figure 6-8 below, inserts into motherboards as follows: • If the 565-274 Master Motherboard is being used, the NIC daughter card is inserted into connector J1. • If the 566-227 Master Motherboard or 565-275 Motherboard is used, the NIC daughter card is inser...

5-11 The nodes in the network now have to be wired together, so that the NIC in one host panel connects to the NIC in the next panel. This section contains guidelines and instructions for NIC wiring. Refer to the following guidelines whenever field wiring the NICs. • Network nodes must be wired righ...

5-12 • 655-158 Transient Suppressor (ordered as part of 748-599) is required for each modem-to-telephone line connection. From Modem 8 5 Grn Telephone Line 1 4 7 6 2 3 Figure 5-8. The Transient Suppressor Maximum wiring distances are shown in the Table below and in Appendix J. Table 5-2. Wiring Dist...

5-13 Connectors U1 (transmitter) and U2 (receiver) on the 4100-6057 Fiber-Optic Media Card are used to connect 4100-6014 NICs across parts of a network. Note: ST connectors with long strain relief boots are to be used with the fiber optic cable. Figure 6-10 shows how two network nodes are connected ...

5-15 The illustration below shows coupler wiring. Figure 5-10. Coupler Wiring Refer to the guidelines and figures in this topic to use wired media cards. IMPORTANT: TB1 on the wired media card must not be used when it is connected to the 4100-6014 NIC. • When the 565-413 Interface Card is used with ...

5-17 The figures below show how to wire the NIC. The illustrations use the 565-274 and 565-275 motherboards only. If you are using the 4100U motherboard, refer to Figure 5-11 along with the figures below. Figure 5-12. Wired Media, Style 7 Wiring Continued on next page Step 4. Wiring Network Cards, C...

5-19 Figure 5-14. Wired Media and Fiber Optic, Style 7 Wiring Step 4. Wiring Network Cards , Continued Wired Media and Fiber Optic, Style 7 Wiring Notes: 1. Refer to general wiring precautions in this chapter, as well as Field Wiring Specifications: document 900-082 for 4100; 900-242 for 4100U. For ...

6-1 The SPS is described in Chapter 2. A picture is shown in Figure 2.4. This chapter has the current and voltage ratings of the system power supply (SPS) and describes how it is installed and configured by the factory. It also describes the Alarm Relay Card that mounts onto the SPS to provide 3 ext...

6-2 The following table summarizes the specifications for the SPS. Table 6-1. SPS Input and Output Specifications AC Input Specifications SPS in Standard Australian FACP 4100-9848AU 2 A Maximum 240 VAC + 6% -10% @ 50 Hz DC Output Specifications Voltage Nominal 28VDC Minimum: 19.5 VDC Maximum: 32 VDC...

6-3 • +24V Sig is used to supply the NACs. It can be made accessible by configuring a NAC as an aux power output (normally energized). The PDI has a 24V Sig bus that is only powered when an SPS is plugged directly on to it. (Not in standard configuration). The 4100 MXP is the only Australian approve...

6-4 The range of possible temperatures under which the SPS may function are between 0 ° C and 50 ° C (120 ° F). The SPS operates normally under non-condensing humidity conditions up to 93% with relative humidity at 32° C. This section contains information about SPS jumpers, DIP switches and potentio...

6-5 The SPS has the following LEDs: LED1 (yellow). Illuminates when NAC 1 is ON or in Fault. LED2 (yellow). Illuminates when NAC 2 is ON or in Fault. LED3 (yellow). Illuminates when NAC 3 is ON or in Fault. LED4 (yellow). Illuminates to indicate a communications loss with the system CPU; normally of...

6-6 This section contains explanations of fault messages that may appear on the 4100U display when using the SPS. Heading text in the left margin shows the error message, while the paragraph next to it describes the likely cause of the message. There is no output voltage from the power supply. Refer...

6-7 The Alarm Relay Card mounts on, and is driven by, the SPS. It has 3 relays each providing one set of voltage-free contacts. The relays are able to be configured under custom control, but the default operation is for system status, i.e. Fault (Trouble), Isolate (Supervisory), and Alarm, respectiv...

6-8 The relays have one set of voltage-free contacts (see note below) connected to one pair of terminals via a header. The two terminals are configured for normally closed or normally open by positioning a jumper on the header. Table 6-3. Alarm Relay Card Jumper Positions Relay Header Normally Close...

7-1 This chapter shows how various devices are wired to an SPS. It includes connection to NACs, IDNet, relays, and power circuits. Refer to the page number listed in this table for information on a specific topic. Topic See Page # General Field Wiring Guidelines 7-2 SPS NAC Field Wiring Guidelines 7...

7-2 Make sure these guidelines are accounted for before wiring: • All field wires must be 0.75 mm 2 or greater and comply with AS1670.1 and the wiring code. • Conductors must test free of all grounds. • All wiring must be done using copper conductors only, unless noted otherwise. • If shielded wire ...

7-3 Each of the 3 NACs has two pairs of driven outputs (A+/A-, B+/B-) which operate together. NAC B outputs have polarity reversal supervision and expect a 10k EOLR. Each connected device must have a suitably rated blocking diode. NAC A outputs have an integral 10k to accommodate Class A (loop) wiri...

7-4 To connect the SPS to reverse-polarity, non-addressable notification appliances using Class A wiring, read the following instructions and refer to the figure below. 1. Route wire (between 0.75 mm 2 and 4 mm 2 ) from the “B+”, “B-”, outputs on TB2 of the SPS to the appropriate inputs on a periphe...

7-5 To connect the SPS to appliances using Class B wiring, read the following instructions and refer to the figure below. 1. Route wire (between 0.75 mm 2 and 4 mm 2 ) from the B+, B- outputs on TB2 of the SPS to the appropriate inputs on a peripheral notification appliance. Use NAC1, NAC2, or NAC3,...

7-7 Table 7-2 lists the maximum distances from the NAC terminal block to the last appliance in a Class B configuration, depending on wire gauge and current. Use Table 7-2 to calculate wire distances for your application if you are using Class B wiring. Table 7-2. Class B Wiring Distances Alarm Curre...

7-8 The panel, battery-backed, unregulated dc bulk power is available from the SPS via the NAC and the 24V Aux power terminals (1 pair only, ref fig 7-4). NACs not configured as switched outputs may be configured as auxiliary power point type in the 4100 Programmer. All of these are power-limited. R...

7-9 The SPS can connect to auxiliary power appliances via the dedicated auxiliary power tap (TB3). If more power is needed, any of the three NAC outputs can be used for EMC auxiliary power. B+ 0V 24V AUX POWER B- A+ A- B+ B- A+ A- B+ B- A+ A- AUXILIARY POWER AUXILIARY POWER AUXILIARY POWER AUXILIARY...

7-10 The SPS has one programmable relay, Aux 1, with one set of voltage-free contacts (see below). It also has provision for mounting a 4100-6033 Alarm Relay that has 3 relays, each with one set of normally open (or normally closed) contacts available on a screw terminal block (see fig 6.1). • The r...

7-11 The Figure below shows the SPS relays. Figure 7-5. Auxiliary Relay & Alarm Relay Card Relays SPS Auxiliary Relay Wiring, Continued Relays B+ B- A+ A- B+ B- A+ A- B+ B- A+ A- TB2 SPS Dedicated Auxiliary 1 relay terminal block NO C NC TB4 TERMINAL BLOCK ALARM RELAY MODULE P7 P4

7-12 This section describes how the IDNet on the SPS connects to addressable devices/detectors. The guidelines governing IDNet wiring guidelines are covered in chpt 8, IDNet Installation. Up to 250 IDNet initiating devices are supported on the SPS IDNet channel. The SPS supports both Class A (loop) ...

7-13 To connect addressable devices/detectors to the SPS IDNet using Class A wiring, read the following instructions. 1. Ferrite beads are required on the SPS IDNet cables (ref Fig 7.1). 2. Route wire (between 0.75 mm 2 and 4 mm 2 ) from the B+, B- outputs on TB1 of the SPS to the appropriate inputs...

7-14 To connect addressable devices/detectors to the SPS IDNet using Class B wiring, read the following instructions. 1. Under AS1670.1 Class B wiring is allowed only for a maximum of 40 addressable devices. 2. A ferrite bead is required on the SPS IDNet cable. 3. On TB1, jumper B+ to A+, and jumper...

8-1 Two loop cards are available in the 4100U 4”x 5”card format. These plug directly onto the PDI and form an intelligent interface between the 4100U CPU and one loop of addressable detectors/devices. The IDNet Card uses Mapnet Protocol and communicates with existing Mapnet detectors/devices plus th...

8-2 The 4100U IDNet card receives 24V power (+24V Card Supply bus) and coms (i.e. communication with the CPU) via the PDI. There are several versions, configured by links soldered on the pcb. The 4100-3101 used in Australia, communicates with up to 250 devices. An IDNet card may be fitted to a 4100 ...

8-3 The IDNet card has the following LEDs: LED1. Normally off. Turns on steady if the IDNet card is not communicating with the 4100 CPU. LED2. Normally off. Illuminates to indicate a problem with the IDNet lines. • Steady on indicates channel failure. • One repetitive blink indicates a line short. •...

8-4 The 4100-series IDNet card is designed to be mounted on the PDI in a 4100U expansion cabinet. The card can be mounted on any of the PDI connectors. Use connector P2, labeled on the back side of the IDNet card, to connect to any of the eight PDI connectors as shown in the figure below. Figure 8-2...

8-5 If a 4100 is upgraded to 4100U, IDNet cards can be fitted to existing 4100 bays by use of the Interface Card plus bracket. The bracket mounts to the bay as a 4100 card motherboard does and takes up 1 slot. Wire detectors and devices Connect Comms and Power with LM0203 Blue +3 Black Blue + 3 Blac...

8-6 Configuring the card consists of selecting the shield tie point, and setting the device address.. If a shielded cable is used, connect the cable shield to the dedicated terminal on TB1 and use jumper port (P1) to select where the shield will be tied. • Position 1 - 2 connects the shield to 0 V. ...

8-7 Up to 250 IDNet slave devices, such as smoke detectors and manual call points, can be connected to the IDNet card using Class A (loop) or Class B (line) wiring, with the following restrictions. Class A wiring allows the devices to communicate with the IDNet card even in the event of an open circ...

8-8 Table 8-2 Cable Run Lengths 1. The circuit allowance per device on the loop is 0.5mA with the LED off, 2mA with the LED on. A maximum of 20 LEDs get turned on at one time by IDNet Card (i.e. in alarm). 2. The minimum voltage allowed at the furthest device to guarantee operation is 24.9Vdc. The I...

8-9 To connect the IDNet card to appliances using Class B wiring, read the following instructions. 1. On TB1, jumper IDNetB+ to IDNet A+, and jumper IDNetB- to IDNetA-. If the jumper is absent, a Class A Trouble will be indicated on LED 2. 2. Route wire between 0.75 mm 2 and 4 mm 2 from the IDNetA+,...

8-10 This section describes the messages that may appear on the 4100 display when using the IDNet card. Trouble messages appear on the left as titles, and possible causes are listed to the right in the text. There is no output voltage from the IDNet power supply. Replace the IDNet card. Appears if o...

9-1 The service port on the door with the Operator Interface enables the 4100U to connect to PCs running important utilities, such as diagnostics, programming, CPU firmware downloading, and channel monitoring. Refer to the page number listed in this table for information on a specific topic. Topic S...

9-2 The 4100U can connect to PCs running important utilities, such as diagnostics, programming, CPU firmware downloading, and channel monitoring. It connects to PCs running all of these utilities via the service port on the CPU daughter card. When a PC is located remotely from the FACP, the 4100-983...

9-3 Master Bootloader Interface Mode. This mode downloads the Master CPU Exec firmware and the CFG.TXT file to the CPU via the serial port. Laptop/PC running terminal emulation software 4100 Panel running Bootloader serial download cable Figure 9-3. Bootloader Interface Software Modes, Continued Sof...

10-1 This chapter provides detail on format and components that are specific to the Australian version 4100U that complies with AS4428. Refer to the page number listed in this table for information on a specific topic. Topic See Page # Summary Of Australian Version Specifics 10-2 Australian Panel Fo...

10-2 The Australian fire alarm standards differ from those in the USA. Shipping costs from USA to Australia are significant, and the Australian market is small compared to the USA market. It is therefore necessary to: • have an Australian specific panel format that differs from the standard USA pane...

10-3 The main difference with the Australian panels is that they are assembled in the Australian (Tyco) range of rack cabinets. Some further specific differences follow: • Only the Expansion Bay is used, with the Controller CPU and Motherboard mounted in the right hand side of the first one. The sta...

10-6 The Alarm Relay Card is typically used to provide a Brigade Interface. The default configuration is for the three relays to operate on Fault (Trouble), Isolate (Supervisory) and Alarm, respectively. The connection drawings for the Centaur ASE, Western Australia AIU and Queensland PPU are includ...

11-1 When a branch designs a system and orders a 4100U panel, a “Configuration Sheet” is prepared. The factory builds the panel to the configuration sheet. This includes fitting, connecting and configuring cards and modules. The factory programs and tests the panel to the configured sheet. The CPU C...

11-3 All the 4100U cards and modules (pcbs) are tested and aligned in the factory before being supplied to the customer or fitted to a FIP. The only field adjustment that may be necessary is to set the battery charger voltage. (Note this has been set and should not need re-adjusting). R341 Battery C...

11-4 To place the 4100U FACP into operation, perform the following steps: STEP 1 Ensure that the Mains Isolate Switch is OFF. STEP 2 Ensure that 240 VAC is connected to the panel from the mains distribution switchboard. STEP 3 Ensure that the Lithium battery is fitted to battery holder on the CPU ca...

11-5 The 4100U system must be kept free from faults and tested on a weekly, monthly and annual basis to verify that it is operating correctly. The tests required by part 8 of the standard AS1851 Maintenance of Fire Protection Equipment are detailed in the 4100U Operator’s Manual, LT0351. The Operato...

A-1 Addressable cards include a bank of eight DIP switches. From left to right (see Figure A-1, below) these switches are designated as SW x -1 through SW x -8. The function of these switches is as follows: • SW x -1 . This switch sets the baud rate for the internal 4100 communications line running ...

A-2 Table A-1. Card Addresses Overview, ( continued ) Address SW 1-2 SW 1-3 SW 1-4 SW 1-5 SW 1-6 SW 1-7 SW 1-8 Address SW 1-2 SW 1-3 SW 1-4 SW 1-5 SW 1-6 SW 1-7 SW 1-8 1 ON ON ON ON ON ON OFF 61 ON OFF OFF OFF OFF ON OFF 2 ON ON ON ON ON OFF ON 62 ON OFF OFF OFF OFF OFF ON 3 ON ON ON ON ON OFF OFF 6...

B-1 This appendix identifies the programming that is required to comply with AS4428. It does not provide equations or detail of programming. The separate 4100 Programming Unit Manual tells how to use the PC-based 4100U Programmer. Refer to the page number listed in this table for information on a sp...

C-1 This appendix contains instructions on how to use a volt/ohm meter to check system wiring. When using the volt/ohm meter to check each circuit, make sure to adhere to the notes and instructions below. Notes: • Ensure that no power is applied to the 4100U fire alarm panel and that all wiring is p...

C-2 Table C-1 lists the correct meter readings for indicating appliances and initiating devices. Table C-1. Acceptable Zone and Signal Circuit Meter Readings Circuit Type Meter Reading Class B/Style B Initiating Device (Zone) Circuit From zone + to zone – (each zone) 3.3 K Ohms From zone + to ground...

D-1 This appendix contains instructions on how to use the Earth Fault Search feature of the 4100U diagnostics menus. Earth Fault Search is a diagnostic search of external field wiring that assists in locating circuits with earth faults. An earth fault occurs when an electrical circuit is shorted to ...

D-3 This section describes how to conduct an Earth Fault Search, from selecting the appropriate access code to correcting the fault. The panel must be at the appropriate access level (1, 2, 3, or 4) in order to run diagnostics. To get to the correct access level, 1. Press the Menu button. The follow...

D-4 8. Press the Enter button. The following options become available when you press the Next and Previous buttons: Press <NEXT> or <PREVIOUS> to scroll Location Search Press <NEXT> or <PREVIOUS> to scroll IDNet Channel Search Press <NEXT> or <PREVIOUS> to scroll ...

D-5 If you select the IDNet Channel Search menu item, a list of IDNet channels to search becomes available. Use the Next and Previous buttons to scroll through the list. When the IDNet channel you want to search is shown and "Press <ENTER> to start search" displays, the search is ready...

D-6 There are several types of results that can display at the end of an Earth Fault Search. This section covers all types of results. IMPORTANT: Once you have been directed to an earth ground fault and corrected it, it is recommended that you restart the system (warm- or cold-start). A non-point fa...

D-7 4009 IDNet NAC Extender/TrueAlert Addressable Controller faults. The message below shows a fault detected on the 4009 IDNet NAC Extender before the repeater connected to that circuit is turned on: CARD 2, IDNET CARD (250 POINTS) M1-18, 4009A NAC EARTH FAULT Conversely, the following example show...

D-8 The illustration below shows a MINIPLEX system with one transponder that has three earth faults: • SPS NAC on the SPS in the Main Panel • RPS AUXPWR output on the RPS in Transponder 1 • IDNet channel in Transponder 1 T ra n s p o n d e r 1 M a in P a n e l R U I S P S N A C 2 R P S A U XP W R Is...

D-9 B. Find and repair the indicated fault on Transponder 1. 1. Select Location Search. 14. Select the RPS located in Transponder 1 (this selects Transponder 1 as the location for the search). 15. When prompted, select exclusion of AUXPWR circuits. 16. Start the search. (The panel turns on the earth...

E-1 The following manuals are relevant. Other Australian 4100 manuals may be found on the TSP website. Book Part Number Title LT0293 4100A FIP AS4428 Operators Manual LT0294 4100A FIP AS4428 Installation Manual LT0295 4100A FIP AS4428 Technical Manual LT0307 4100 Field Wiring Diagrams LT0313 4100 MX...

E-3 Book Part Number (cont.) Title (cont.) 579-175 4100U Class A and Expansion NAC Modules Installation Instructions 579-229 4100U Upgrade Kits Installation Instructions 579-246 4100U SPS/RPS Installation Instructions 579-248 4100-0632 Terminal Block Utility Module Installation Instructions 579-331 ...

F-1 This appendix describes the following: • It lists devices that have been approved as compatible devices for use with the 4100A/4100U FIP. • It lists the devices approved for use with the IDNet and shows the number allowed per loop. Refer to the page number listed in this table for information on...

F-2 Hochiki Range - Conventional Detectors DCA-B-60R MK V Type A heat detector DCC-A Heat Type A DCC-C Heat Type C DCD-A Heat Type A DCD-C Heat Type C DFE-60B Type B heat detector DCA-B-90R MK 1 Type C heat detector DFE-90D Type D heat detector DFG-60BLKJ Type B heat detector DFJ-60B Heat Type B DFJ...

F-4 Simplex MAPNET 2 Range – Addressable Field Devices 2190-9156 Mapnet 2 Monitor ZAM 2190-9162 Mapnet 2 Signal ZAM 2190-9164 Mapnet 2 Control ZAM 2190-9169 Mapnet 2 Line Powered Short Circuit Isolator 2190-9172 Mapnet 2 Supervised IAM 2190-9173 Mapnet 2 Loop powered 2 Point Input / Output Module 40...

F-5 The following lists the addressable devices approved for use with IDNet and shows current rating and numbers allowed per loop. Device Type Operating Current mA Maximum Addressable Point On Analogue Loop Maximum Addressable Points on Analogue Line 4090-9116 IDNet Comms Isolator 0.5 (2 with LED on...

G-1 The following batteries are compatible with the 4100U. • Power Sonic PS12 Series • Century Power Sonic PS12 series • Sonnenschein A200 Series • Sonnenschein A300 Series • Century Yuasa NP Series • Auscell CJ12 series • Power Block PB12 series Appendix G Compatible Batteries

H-1 System Capacity 2,000 points of addressable points, plus 2,000 points of annunciation. Expansion Up to capacity above. Up to 119 Addressable cards Cabinet Size Dependent on system configuration Cabinet Material 1.6mm Zintex Cabinet Finish Powder coated Cabinet Colour Cream Wrinkle Mounting Wall ...

H-2 The DC input voltage range of the following modules is 18-33Vdc. The current listed is nominal for 24Vdc, and may be used for battery capacity calculations. Module Name Quiescent Alarm N/A Master Controller Assembly (includes SPS, CPU, CPU Motherboard with RUI I/F, Operator Interface with LCD) 3...

I-1 Part of the system design includes calculating that the quiescent load and the alarm load are each less than the rating of the power supply. Note that the quiescent load includes devices such as door holders that are normally energized, but get switched off during alarm. The SPS rating is includ...

J-1 The IDNet cabling requirements are detailed in Chapter 8 of this manual. Line Characteristics Note: In the following paragraphs the term "MAPNET channel" is used to mean those lines connected to any one Mapnet Transceiver board. Parallel runs from the same board do not constitute separat...